DE202014100732U1 - anchorage - Google Patents

Abstract

Sling eyelet comprising an eyelet lower part (2) which can be fixed to an object and an eyelet part (3) which can be rotated relative to the eyelet lower part (2) and has a fixed eyelet bracket (7), characterized in that the eyelet bracket (7) is in the region of its apex (13) at its Side surfaces (14, 14.1) each have a projection (15, 15.1) with a vertex (17) to prevent any significant tensile stress on the lifting eye (1) in the vertex (13) of the eyelet bracket (7) in the direction transverse to the central longitudinal plane (16) of the eyelet bracket ( 7), the vertices (17) of the projections (15, 15.1) running in the direction of the height of the eyelet bracket (7) in the region of its apex (13) are located on a plane that is perpendicular to the central longitudinal plane (16) of the eyelet bracket ( 7) and through which the axis of rotation of the eyelet part (3) is passed.

Description

The invention relates to a stop lug comprising a fixable on an object Ösenunterteil and a relative to the Ösenunterteil rotatable eyelet with a fixed eyelet.

Such eyelets are typically used for lifting objects. For this purpose, the lifting lugs have a connection means, such as a terminal screw, to be connected to the object. The stop eyes in question comprise a Ösenunterteil and a relative to the Ösenunterteil rotatable eyelet. The rotating eyelet has a fixed eyelet. For the purpose of rotatability of the eyelet against the Ösenunterteil a corresponding storage is provided. This can be carried out for minimizing friction ball or roller assisted. For lifting or lashing an object, typically several stop eyes are connected to the object. If such an object equipped with a plurality of lifting eyes is to be lifted, a lifting means, for example a multi-stranded hook chain, is typically used for this purpose. The rotatable arrangement of the eyelet with respect to the Ösenunterteil causes suspended by a hung in an eyelet hoist, typically a hook when placed under appropriate tensile load, the eyelet according to the pulling direction acting thereon.

Such a lifting lug must, in order to be qualified for a certain quality or load level, meet the corresponding load requirements. Previously known lifting eyes usually meet these requirements when the load tensile force is introduced in the central longitudinal plane of the Ösenbügels in this. However, the quality requirements also relate to a tensile load of the stop lug, which acts transversely to the central longitudinal plane of the Ösenbügels. These requirements usually do not meet conventional lifting eyes.

Based on this discussed prior art, the invention is therefore the object of developing a lifting lug of the type mentioned in such a way that no loss of minimum load capacity must be accepted by the transverse load.

This object is achieved according to the invention by an aforementioned, generic stop lug, wherein the Ösenbügel in the region of its apex on its side surfaces each having a vertex-bearing projection to prevent a significant tensile stress of the lug in the apex of the Ösenbügels in the transverse direction to the central longitudinal plane of the Ösenbügels wearing in the direction of the height of the Ösenbügels extending in the region of its apex vertexes of the projections are located on a plane which is perpendicular to the central longitudinal plane of the Ösenbügels and through which the axis of rotation of the Ösenteils is passed.

This lifting lug is designed so that a significant Zuglastangriff is prevented on the vertex of the Ösenbügels when a load application, such as a lifting or lifting means, such as a hook is connected to the Ösenbügel. Due to the special design of the apex of the Ösenbügels with its projecting from the side surfaces a tensile load attack in the transverse direction to the central longitudinal plane of the Ösenbügels or Ösenteils made impossible that at this critical for a lateral force load attack position for a force introduction means, such as a crane hook no stable Plant is possible.

Upon application of a certain tensile force, the force introduction means slips off the apex of the projection on which this should abut, and is moved out of alignment with the axis of rotation of the eyelet by slipping off the apex of this projection. For this purpose, the vertices of the projections lie on a plane which is perpendicular to the central longitudinal plane of the Ösenbügels and through which the axis of rotation extends. Thus, if the hook as an exemplary force introduction means slipped from such a projection, the tensile load attack is no longer in the alignment of the axis of rotation of the eyelet. A further Zuglastbeanspruchung the Ösenteils causes a torque is introduced into the eyelet on the Ösenbügel through which the Ösenbügel aligns in the direction of the applied tensile force and is then in a position in which the applied tensile force in turn in the central longitudinal plane of the Ösenbügels is initiated in this. In this direction of force introduction the stop lug satisfies the load requirements imposed on them. Thus, the projections cause by their prevention of the introduction of a tensile force in a position of the eyelet, in which this does not align in the direction of the applied tensile force, to increase the nominal load capacity of the stop lug in this transverse direction. It is noteworthy that this is surprisingly possible with such simple means - with the projections. In this way, the stop lug also satisfies the loads required in the transverse direction without having to use significantly more material for forming the eyelet or the eyelet strap. At eyelets of the type in question, the eyelet is executed in many cases as a forged part. Without Further depressions can be introduced as a negative of the projections to be formed in the dies in the apex of the Ösenbügels.

The projections are made so that, as already mentioned, a stable investment of a traction device on the apex of the projections, so in a Querzuglastbeanspruchung the stop lug with a force in the apex of the Ösenbügels is not given. For this reason, one will perform the apex of the protrusions with a small radius. This radius is many times less than the radius of a force-introducing traction means applied thereto, for example a hook. The flanks of the projections are preferably straight or concave. This has the advantage that the flanks of the projections adjoining the apex are relatively steep. These typically have a slope of less than 45 ° with respect to an imaginary vertex connection line in their crest-near portion. Quite an angle of only 30 ° are conceivable. The concave design of the flanks of the projections favors slippage of a seated on the apex of a projection traction means in one or the other direction. Here, it is irrelevant whether the force in the Ösenbügel initiating traction means, so for example, a hook on a lifting harness of this, in one or the other direction to the Ösenbügel out at a Zuglastbeanspruchung slips, as a result of the rotational movement of the Ösenteils against the Ösenunterteil itself this will always align in the direction of the tensile load, albeit with different direction of rotation. However, this is irrelevant for a use of the stop lug. So that the projections of the installation of a force introduction means, such as a hook, is not hindered at the Ösenunterteil facing inside of the Ösenbügels, the projections have only a limited height, with which they protrude from the side surfaces of the Ösenbügels on. It is also preferred that the projections in the direction of the height of the Ösenbügels are also curved.

The invention is described below with reference to an embodiment with reference to the accompanying figures. Show it:

1 FIG. 4 is a partially sectioned view of a stopper according to an embodiment of the invention. FIG.

2 a cross-section through the apex of the Ösenbügels the lifting eye of 1 along the line AB,

3 : a plan view of the stop lug of the 1 .

4 : the top view of the stop lug according to 3 at the beginning of applying a tensile force on the region of the apex of Ösenbügels in a transverse load and

5 : the lifting eye in the position of its Ösenbügels after aligning the same in the direction of the applied tensile force.

A stop eyelet 1 has a Ösenunterteil 2 and over an eyelet 3 , The eyelet base 2 of the illustrated embodiment is designed as a bearing bush, which in turn consists of two bearing bush parts 4 . 4.1 is composed. Each of the two bearing bush parts 4 . 4.1 has a leg projecting radially outward. Both legs are spaced apart. In the thus formed circumferential groove of Ösenunterteils 2 engages a bearing flange 5 of the eyelet 3 one. The eyelet 3 includes a main body 6 that the bearing flange 5 carries, as well as a fixed eyelet strap 7 , Fixed is the eyelet 7 therefore, since this opposite the main body 6 is not swiveling. The bearing flange 5 is with the necessary movement play between the two spaced apart legs of the bearing bush parts 4 . 4.1 held to the desired rotational mobility of the eyelet 3 opposite the eyelet 2 to allow.

The eyelet base 2 has a central opening into which a connection screw 8th with its threaded shaft 9 intervenes. In this way, the Ösenunterteil 2 by means of the connection screw 8th can be connected to an object and fixed to it. The connection screw 8th is in the opening of the Ösenunterteils 3 by means of a snap ring 10 held in one of the threaded shank 9 subsequent thread-free section of the connection screw 8th introduced groove 11 and in an inside of the bearing bush part 4 introduced groove 12 intervenes.

In the area of the vertex 13 the eyelet strap 7 on each one is the inside of the earhook 7 with its outside connecting side surface 14 . 14.1 a lead 15 . 15.1 , The design and arrangement of the projections 15 . 15.1 is better from the cross section of the 2 through the crown 13 the eyelet strap 7 recognizable. The two projections 15 . 15.1 are mirror-symmetrical to the central longitudinal plane of the Ösenbügels 7 intended. The central longitudinal plane of the Ösenbügels 7 is in the 2 and 3 with the reference number 16 indicated. The in 2 shown section through the eyelet 7 shows the track of the central longitudinal plane 16 , In the cutting plane this is at the same time the axis of rotation of the eyelet bracket 7 , The projections 15 . 15.1 are like, out 3 recognizable, on a common plane, spanned by the vertical extent of the vertex 17 the projections 15 . 15.1 , This plane is perpendicular to the median longitudinal plane 16 the eyelet strap 7 arranged. The rotation axis 18 is through the the tops 17 the projections 15 . 15.1 connecting level passed. In the illustrated embodiment, the axis of rotation is located 18 within the aforementioned, the projections 15 . 15.1 connecting level. At the same time is the axis of rotation 18 of the eyelet 7 in the central longitudinal plane 16 the eyelet strap 7 ,

The following is the lead 15 described in more detail. The same statements apply equally to the lead 15.1 , As seen from the sectional view of 2 recognizable, is the vertex 17 of the lead 15 in the direction of the height of the eyelet hanger 7 in the area of his crown 13 curved. Consequently, the height of the projection decreases 15 towards the eyelet bottom 2 facing inside and to this opposite outside of the eyelet bracket 7 from. Curved is the lead 5 also in the transverse direction (see 3 ). The height of the projection 15 , with this of the side surface 14 protrudes, in this embodiment is about 20% of the width b of the Ösenbügels 7 in the area of his to the projection 15 adjacent side surface portions. The lead 15 has in the illustrated embodiment has concave flanks, as shown in the representation of 3 seen. The vertex edged by the flanks 17 is rounded, and executed with a relatively small radius. This ensures that a rigid force attachment, such as a hook, happens to be on the vertex 17 of the lead 15 rests on a tensile stress inevitably slipping from this in one or the other direction and then to the adjacent to the projection 15 attacking bracket section attacks because he finds a plant there only.

4 shows an introduction of force in the eyelet 7 , immediately after applying a first tensile force, by means of a hook on the vertex 17.1 of the lead 15.1 exercised. As previously described, this application of force results in the hook being in one or the other direction from the projection 15.1 slip. In the in 4 example shown, the hook slipped to the left, so that an introduction of force through the hook in the eyelet 7 after this desired position shift no longer in the flight of vertex 17.1 of the lead 15.1 with the rotation axis 18 of the eyelet 3 opposite the eyelet bottom 2 he follows. The force attack takes place from now on at a distance from the axis of rotation 18 , The attacking force is in 4 indicated with a block arrow. This causes after the intended position shift of the hook, the introduction of a torque in the eyelet 7 and thus into the eyelet 3 , which will align with the applied force in the direction of the applied force, thus in the described example counterclockwise, as indicated by the arrow, will rotate. This rotation is finished when the central longitudinal plane 16 the eyelet strap 7 points in the direction of the applied force. This position of the eyelet 3 opposite the eyelet bottom 2 is in 5 shown. For a force application in this direction is the stop lug 1 designed.

The description of the embodiment makes it clear that by preventing an introduction of force into the eyelet 3 or the eyelet strap 7 in the crown 13 the eyelet strap 7 in a position in which the point of application of the tensile force and the direction of the tensile force with the axis of rotation 18 aligned, is effectively prevented, by providing the projections 15 . 15.1 , which do not allow a stable installation of a force connection means at this point. The result is that such a lifting eye in this direction withstands the required loads.

LIST OF REFERENCE NUMBERS

1

anchorage

2

Ösenunterteil

3

eyelet

4, 4.1

Bushing part

5

Lagerflansch

6

body

7

Ösenbügel

8th

terminal screw

9

threaded shaft

10

snap ring

11

groove

12

groove

13

vertex

14, 14.1

side surface

15, 15.1

head Start

16

Central longitudinal plane

17

vertex

18

axis of rotation

b

width

Claims (7)

Lifting eye comprising a Ösenunterteil fixable to an object ( 2 ) and one opposite the Ösenunterteil ( 2 ) rotatable eyelet ( 3 ) with a fixed eyelet ( 7 ), characterized in that the eyelet ( 7 ) in the area of his crown ( 13 ) on its side surfaces ( 14 . 14.1 ) each have a vertex ( 17 ) ( 15 . 15.1 ) to prevent a significant tensile stress of the stop lug ( 1 ) in the vertex ( 13 ) of the eyelet bracket ( 7 ) in the transverse direction to the central longitudinal plane ( 16 ) of the eyelet bracket ( 7 ), wherein in the direction of the height of the Ösenbügels ( 7 ) in the area of his vertex ( 13 ) extending vertices ( 17 ) of the projections ( 15 . 15.1 ) are on a plane which is at right angles to the central longitudinal plane ( 16 ) of the eyelet bracket ( 7 ) and through which the axis of rotation of the eyelet ( 3 ) is passed. Lifting eye according to claim 1, characterized in that the projections ( 15 . 15.1 ) have concave shaped flanks. Lifting eye according to claim 2, characterized in that the angle of inclination of the flanks in the region of the transition into the vertex ( 17 ) is smaller than 45 ° with respect to an imaginary vertex connection line between the two projections. Lifting eye according to one of claims 1 to 3, characterized in that the vertex ( 17 ) of the projections ( 15 . 15.1 ) is executed rounded. Lifting eye according to one of claims 1 to 4, characterized in that the height of each projection ( 15 . 15.1 ) more than 15% of the width (b) of the projections ( 15 . 15.1 ) adjacent portion of the Ösenbügels ( 7 ) corresponds. Lifting eye according to claim 5, characterized in that the height of each projection ( 15 . 15.1 ) between about 20% and 30% of the width (b) of the projections ( 15 . 15.1 ) adjacent portion of the Ösenbügels ( 7 ) is. Lifting eye according to one of claims 1 to 6, characterized in that the height of the projections ( 15 . 15.1 ) is less than 50% of its width.

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